KR102163915B1 - Smart watch and method for controlling thereof - Google Patents

Abstract

The present specification relates to a smart watch and a control method thereof for enabling a user to control the smart watch more conveniently and more accurately.
According to an exemplary embodiment disclosed for this purpose, there is provided a smart watch, comprising: a tilt sensor unit sensing a tilt of the smart watch; a display unit displaying an image; And a processor that controls the tilt sensor unit and the display unit. Including, wherein the processor, when the front of the display unit is facing a predetermined direction, when sensing that the smart watch rotates in a first direction based on an axis of rotation of the smart watch , Using the inclination sensor unit to obtain a first rotation angle in the first direction, and when the first rotation angle exceeds a first threshold angle, corresponding to the first direction When performing a first command and sensing that the smart watch rotates in a second direction based on the rotation axis, a second rotation angle in the second direction is obtained using the tilt sensor unit, and the second rotation angle is obtained. 2 When the rotation angle exceeds the second threshold angle, a second command corresponding to the second direction is executed, wherein the first direction is an opposite direction to the second direction, and the first The threshold angle is greater than the second threshold angle to provide a smart watch.

Description

Smart Watch and Control Method {SMART WATCH AND METHOD FOR CONTROLLING THEREOF}

The present specification relates to a smart watch and a control method, and more particularly, to a device that performs various commands according to the rotation direction and rotation angle of the smart watch.

With the development of technology, the development of wearable computers is accelerating. Here, the wearable computer refers to a computer that can be worn on the body naturally, such as clothes, watches, glasses, and accessories. Smartphones and tablet PCs can be conveniently used with a single finger or touch pen, but there may be inconveniences of carrying them in a pocket or bag or carrying them in their hands. On the other hand, wearable computers can be more portable than smartphones or tablet PCs because they can be worn on the wrist or worn like glasses. In particular, as a type of wearable computer, a variety of products for a wrist watch, that is, a smart watch, capable of searching various services such as diary, message, notification, stock quote, etc. through wireless, have appeared.

Since the smart watch is worn on the user's wrist, it is possible to detect various user's arm movements. In this case, it is possible for the user to more easily control the device by responding to various commands to the detected user's arm movement. In particular, the smart watch can be set to perform a certain command according to the rotation gesture of the wrist. At this time, if the same threshold angle is specified for the inner and outer rotational directions of the smart watch, the smart watch may operate contrary to the user's intention. This is because, depending on the structure of the human body, the radius of rotation of the inside and outside of the wrist may be different depending on the current arm position. Therefore, it is necessary to designate different threshold angles according to the rotation direction in order to prevent such a malfunction of the smart watch.

According to an embodiment, the present specification is to provide a smart watch that executes commands corresponding to each other according to a rotation direction and a rotation angle of a device.

In addition, according to another embodiment, the present specification is to provide a smart watch that provides a threshold angle for executing a command differently according to the position and rotation direction of the smart watch.

Further, according to another embodiment, the present specification is to provide a smart watch for determining a command corresponding to rotation of the smart watch according to an application currently being executed or displayed.

In addition, according to another embodiment, the present specification provides a smart watch that executes a command corresponding to the event according to the sensed rotation of the smart watch when an event occurs and the rotation of the smart watch is sensed within a preset time. I want to.

In addition, according to another embodiment, the present specification is to provide a smart watch that executes a command according to the rotation of the smart watch when the rotation speed of the smart watch exceeds a preset speed.

In addition, according to another embodiment, the present specification is to provide a method of controlling an external device paired with the smart watch according to the rotation of the smart watch.

In order to solve the above problem, according to an embodiment, there is provided a smart watch, comprising: a tilt sensor unit that senses a tilt of the smart watch; a display unit that displays an image; And a processor that controls the tilt sensor unit and the display unit. Including, wherein the processor, when the front of the display unit is facing a predetermined direction, when sensing that the smart watch rotates in a first direction based on an axis of rotation of the smart watch , Using the inclination sensor unit to obtain a first rotation angle in the first direction, and when the first rotation angle exceeds a first threshold angle, corresponding to the first direction When performing a first command and sensing that the smart watch rotates in a second direction based on the rotation axis, a second rotation angle in the second direction is obtained using the tilt sensor unit, and the second rotation angle is obtained. 2 When the rotation angle exceeds the second threshold angle, a second command corresponding to the second direction is executed, wherein the first direction is an opposite direction to the second direction, and the first The threshold angle is greater than the second threshold angle to provide a smart watch.

According to an embodiment, since the threshold angle for executing a command is provided differently according to the position and rotation direction of the smart watch, there is an effect of providing a method of controlling a smart watch in consideration of a user's body structure. Through this, when performing a command through rotation of the smart watch, there may be an effect of preventing a malfunction of the device.

In addition, according to another embodiment, since a command corresponding to the rotation of the smart watch is determined according to an application currently being executed or displayed, the present specification has an effect that it is possible to provide a quicker and more convenient method of controlling the smart watch. .

In addition, according to another embodiment, since the command corresponding to the event is executed according to the rotation of the smart watch sensed within a preset time after the event occurs, the present specification provides a more intuitive and convenient smart watch control method. There is an effect that you can.

In addition, according to another embodiment, when the rotation speed of the smart watch exceeds a preset speed, a command is executed according to the rotation of the smart watch, so that a malfunction of the device can be prevented.

More specific effects of the invention will be described later in detail.

1 shows a block diagram of a smart watch of the present specification.
2 and 3 are diagrams illustrating a user's wearing state of a smart watch according to an exemplary embodiment.
4 and 5 are diagrams illustrating a smart watch rotating about a rotation axis according to an exemplary embodiment.
6 is a diagram illustrating a smart watch that executes a command according to rotation of the smart watch, according to an exemplary embodiment.
7 is a diagram illustrating a smart watch in which an event has occurred according to an exemplary embodiment.
8 is a diagram illustrating a smart watch that executes a command in response to a rotation speed according to an exemplary embodiment.
9 is a flowchart illustrating a method of controlling a smart watch according to an exemplary embodiment.

The terms used in the present specification have been selected as currently widely used general terms as possible while taking functions in the present specification into consideration, but this may vary according to the intention, custom, or the emergence of new technologies of technicians in the art. In addition, in certain cases, there are terms arbitrarily selected by the applicant, and in this case, the meaning will be described in the description of the corresponding embodiment. Therefore, it should be noted that the terms used in the present specification should be interpreted based on the actual meaning of the term and the entire contents of the present specification rather than the name of the term.

Furthermore, the embodiments will be described in detail with reference to the accompanying drawings and contents described in the accompanying drawings, but are not limited or limited by the embodiments.

1 shows a block diagram of a smart watch of the present specification. In the present specification, a smart watch includes a display unit 1010, a tilt sensor unit 1020, a measurement unit 1030, a camera unit 1040, an input sensor unit 1050, a communication unit 1060, and a processor 1070. can do.

The display unit 1010 may output an image on a display screen. Also, the display unit 1010 may output an image based on content executed by the processor or a control command of the processor 1070. For example, the content may include various videos, images, text, and the like. In particular, in the present specification, the display unit 1010 may display a notification for an event occurring in the smart watch. In addition, in this specification, the display unit 1010 may display a directional indicator to indicate the rotation direction of the smart watch. A detailed description of this will be described later with reference to FIGS. 6 and 7.

The tilt sensor unit 1020 may sense the tilt of the smart watch. In more detail, the tilt sensor unit 1020 may sense the tilt direction and degree of tilt of the smart watch using at least one sensor mounted on the smart watch, and transmit the sensing result to the processor 1070. have. Alternatively, the tilt sensor unit 1020 may sense the rotation direction and rotation angle of the smart watch using at least one sensor mounted on the smart watch, and transmit the sensing result to the processor 1070. In this case, the tilt sensor unit 1020 may include a plurality of sensing means. As an embodiment, the plurality of sensing means is a gravity sensor, a geomagnetic sensor, a gyro sensor, an acceleration sensor, an inclination sensor, an altitude sensor, a depth sensor, a pressure sensor, a gyroscope sensor, a proximity sensor, an angular velocity sensor, a proximity sensor, and a global positioning system (GPS). System) It may include various sensing means such as sensors. In addition, in this specification, the tilt sensor unit 1020 may collectively refer to the above-described various sensing means.

The measurement unit 1030 may measure the rotation speed of the smart watch. In more detail, when sensing the rotation of the smart watch, the measurement unit 1030 may measure the rotation speed of the smart watch using at least one sensor mounted on the smart watch. Furthermore, the measurement unit 1030 may transmit the measured rotational speed to the processor 1070. In this case, the measurement unit 1030 may include a plurality of sensing means. As an embodiment, the plurality of sensing means may include various sensing means such as an acceleration sensor, an angular velocity sensor, a rotational speed sensor, a stroboscope sensor, a magnetic pickup sensor, and a taco generator sensor. In addition, in the present specification, the measurement unit 1030 may collectively refer to the above-described various sensing means.

The camera unit 1040 may capture the front of the smart watch. In more detail, the camera unit 1040 may capture an image in the field of view and transmit the capturing result to the processor 1070. In particular, the camera unit 1040 may capture a user image in the field of view and transmit the capturing result to the processor.

The input sensor unit 1050 may sense an input for a smart watch. In more detail, the input sensor unit 1050 may sense an input for a smart watch and transmit the sensing result to the processor 1070. For example, the input sensor unit 1050 may sense a touch input to the rear surface of the smart watch using at least one sensor, and may transmit the sensing result to the processor 1070. As another example, the input sensor unit 1050 may sense a preset input for a buckle provided in the smart watch using at least one sensor, and may transmit the sensing result to the processor 1070. In this case, the input sensor unit 1050 may include a plurality of sensing means. As an embodiment, the plurality of sensing means may include various sensing means such as a proximity sensor, an infrared sensor, a temperature sensor, a touch sensor, a motion sensor, and a camera sensor. The processor 1070 may determine the mode of the smart watch based on the sensing result transmitted by the input sensor unit 1050. A more detailed description of the smart watch mode will be described later with reference to FIG. 2.

The communication unit 1060 may communicate with an external device using various protocols, and transmit/receive data through this. In addition, the communication unit 1060 may transmit/receive digital data such as content and images by connecting to a network by wire or wirelessly. In particular, in this specification, the smart watch may perform pairing with an external device using the communication unit 1060. Also, the smart watch may perform communication connection with an external device using the communication unit 1060. The paired external device may be controlled through the smart watch, and a detailed description thereof will be described later with reference to FIG. 6.

The processor 1070 may execute various applications by processing data inside the device. In addition, the processor 1070 may execute a certain command according to an input to the smart watch, more specifically, a rotation input of the smart watch. The processor 1070 controls each unit of the above-described device, and may control data transmission/reception between units.

The processor 1070 may obtain a rotation direction and a rotation angle of the smart watch using the tilt sensor unit 1020, and execute a certain command according to the obtained rotation direction and rotation angle. In this case, the processor 1070 may differently designate a threshold angle at which a command can be executed according to the sensed rotation direction. For example, when the processor 1070 senses that the smart watch rotates in an outward direction based on a rotation axis, the processor 1070 may execute the first command when the rotation angle exceeds the first threshold angle. Conversely, when the processor 1070 senses that the smart watch rotates in an inward direction with respect to the rotation axis, the processor 1070 may execute the second command when the rotation angle exceeds the second threshold angle. In this case, according to an embodiment, the first threshold angle may be greater than the second threshold angle. This is to prevent malfunction of the smart watch by designating the threshold angle differently according to the rotation direction in consideration of the user's physical structure. A more detailed description of this will be described later with reference to FIG. 4.

In addition, the processor 1070 may detect a wearing mode or a non-wearing mode using the input sensor unit 1050. As an embodiment, when a user input to the rear of the smart watch is not detected, the processor 1070 may determine the mode of the smart watch as a non-wear mode. Alternatively, when a user input to the rear side of the smart watch is detected, the processor 1070 may determine the mode of the smart watch as the wearing mode. As another embodiment, when a preset input to the buckle of the smart watch is not detected, the processor 1070 may determine the mode of the smart watch as the non-wear mode. Alternatively, when a preset input to the buckle of the smart watch is detected, the processor 1070 may determine the mode of the smart watch as the wearing mode. In this case, a preset input to the buckle of the smart watch may indicate a state in which the buckle is filled. That is, the mode of the smart watch may be determined based on whether the buckle of the smart watch is filled.

As such, the processor 1070 may determine the mode of the smart watch using the input sensor unit 1050. Furthermore, the processor 1070 may execute a certain command based on the determined mode of the smart watch. A more detailed description of this will be described later in connection with FIG. 2.

Also, the processor 1070 may detect an image of the user using the camera unit 1040. As an embodiment, the processor 1070 may detect a user's face located in the field of view using the camera unit 1040. As another embodiment, the processor 1070 may detect the gaze of a user located in the field of view using the camera unit 1040. When the user's face and/or gaze is detected, the processor 1070 may execute a certain command according to the rotation of the smart watch. A more detailed description of this will be described later with reference to FIG. 3.

Meanwhile, although not shown in FIG. 1, the smart watch of the present specification may optionally include a power unit and an audio input/output unit.

The power unit (not shown) is a power source connected to a battery inside the smart watch or an external power source, and may supply power to the smart watch.

The audio input/output unit (not shown) may include an audio output means such as a speaker or earphone. The audio input/output unit may output audio based on content executed by the processor 1070 or a control command of the processor 1070. In particular, in the present specification, when an event occurs in the smart watch, the audio input/output unit may provide voice notification for the event. In addition, in the present specification, the audio output unit may provide a directional indicator for indicating the direction of the rotation gesture for controlling the smart watch as a voice.

Hereinafter, when each step or operation performed in the smart watch is initiated or progressed by sensing an input to the smart watch, the process of generating and receiving a signal according to the sensed input will be described above without overlapping description. It is assumed that the explanation is included. In addition, it may be expressed that the processor 1070 controls the smart watch or at least one unit included in the smart watch according to an input, and the processor 1070 and the smart watch may be identified and described.

Meanwhile, the smart watch shown in FIG. 1 is a block diagram according to an embodiment, and the separated blocks are shown by logically distinguishing elements of the smart watch. Accordingly, the elements of the smart watch described above may be mounted as one chip or as a plurality of chips according to the design of the smart watch.

2 is a diagram illustrating a user's wearing state of a smart watch according to an exemplary embodiment.

The smart watch may include a smart watch body and a band to be worn on the user's arm 2010 as shown in the drawing. If there are a plurality of bands, the smart watch may additionally include a connecting portion (or buckle) 2030 for connecting the plurality of bands. However, the shape of the smart watch shown in the drawings is only an example, and if it is a shape that can be worn on the user's arm, it can be freely changed.

Since the smart watch is small in size and used by being worn on the user's arm, portability and accessibility are very high. In particular, since it is worn and used on the arm, which is a part of the body that the user uses most and freely, it is possible to control the smart watch more easily by responding to a certain command according to the movement of the user's arm. Accordingly, in the present specification, a control method capable of controlling a smart watch more easily and conveniently by corresponding to a certain command to the user's wrist rotation gesture is provided.

However, in this case, a threshold angle for command execution may be provided according to the position and rotation direction of the smart watch. In this case, the threshold angle may be differently specified according to the rotation direction. This is because the turning radius is different depending on the position and rotation direction of the smart watch.

More specifically, as shown in the drawing, when the user wears the smart watch so that the display unit 2020 is positioned on the same side as the back of the hand 2010, the user wears the back of the hand 2010 wearing the smart watch. You can often make gestures of raising your arms to get into your vision. In other words, the user can frequently make a gesture to make the back of the hand 2010 substantially parallel to the ground surface. This is because the user positions the wrist so that the display unit 2020 is positioned in the user's field of view in order to check the contents or images displayed on the display unit 2020. In this case, when the user rotates the wrist about the rotation axis of the wrist, the rotation angle in the outward direction may be large, but the rotation angle in the inward direction may be small. In other words, when the user rotates the wrist as much as possible in the outward or inward direction about the rotation axis in the above-described arm position state, the rotation angle in the outer direction may be greater than the rotation angle in the inner direction. This is because, according to the structural characteristics of the arm, humans can rotate the arm within a preset angle range.

Considering the above points, if the same threshold angle for command execution is provided regardless of the position and rotation direction of the smart watch, despite the difference in rotation angle, a malfunction of the smart watch may occur. For example, if 50˚ is specified as the threshold angle for command execution for rotation in the outward and inward directions, the user can easily input the command in the outward direction, but the command in the inward direction. This may be difficult or may be impossible to input depending on the user. This is because there is a limit to rotation inward in the position of the wrist described above. Accordingly, a threshold angle for executing a command in the inward direction may be smaller than a threshold angle for executing a command in the outward direction.

That is, since the rotation in the outward direction is freer than the rotation in the inward direction and the rotation radius is large, the threshold angle in the outward direction may be specified to be larger than the threshold angle in the inward direction. In other words, since the rotation in the inward direction is limited compared to the rotation in the outward direction and the rotation radius is small, a threshold angle in the inward direction may be specified to be smaller than the threshold angle in the outward direction. Through this, errors that may occur in the execution of commands according to the rotation of the smart watch can be prevented in advance.

As described above, since the smart watch of the present specification performs a command according to a rotation direction and a rotation angle in a preset position state of the wrist, there is a need to detect the current position state of the wrist. The position state of the wrist can be detected by detecting the position state of the smart watch worn on the wrist. The position state of the smart watch can be detected by detecting the user's image using a camera unit or by detecting the tilt state of the smart watch using a tilt sensor unit.

More specifically, when the smart watch detects a user's image, the position state of the smart watch described above may be detected by detecting at least one of the user's face and gaze through the camera unit. Alternatively, when detecting the inclination state of the smart watch, the position state of the smart watch may be detected by acquiring the current inclination of the smart watch through the inclination sensor unit. A more detailed description of the method for detecting the position state of the smart watch will be described later with reference to FIG. 3.

Meanwhile, the command execution according to the rotation of the smart watch is based on a rotation gesture while the smart watch is worn on the user's wrist. Accordingly, according to an embodiment, the smart watch may first detect whether the smart watch is worn on the user's wrist prior to detecting the position of the smart watch described above. In more detail, the smart watch may detect a wearing mode or a non-wearing mode as a mode of the smart watch through the input sensor unit described above with reference to FIG. 1. When a preset input is sensed through the input sensor unit, the smart watch may detect the current smart watch mode as the wearing mode, and then detect the position of the smart watch. Conversely, if a preset input through the input sensor unit is not sensed, the smart watch may detect the current smart watch mode as a non-wearing mode, and then may not detect the position of the smart watch. That is, in the wearing mode, the smart watch may execute a certain command according to the position state, rotation direction, and rotation angle of the smart watch.

As such, the smart watch of the present specification may be controlled according to the position state, rotation direction, and rotation angle of the smart watch. In particular, when the smart watch is in a preset position, a certain command may be executed according to the rotation direction and rotation angle of the smart watch. In this case, the preset state of the smart watch may represent a case in which the front face 2020 of the display unit of the smart watch faces a preset direction, and a more detailed description thereof will be described later with reference to FIG. 3.

Meanwhile, hereinafter, for convenience of description, the outer direction may be referred to as a first direction and the inner direction may be referred to as a second direction. In addition, a command corresponding to rotation in a first direction may be referred to as a first command, and a command corresponding to rotation in a second direction may be referred to as a second command. Furthermore, a threshold angle for executing a command corresponding to the first direction may be referred to as a first threshold angle, and a threshold angle for executing a command corresponding to the second direction may be referred to as a second threshold angle. .

3 is a diagram illustrating a user's wearing state of a smart watch according to an exemplary embodiment. In more detail, a diagram for explaining a preset position state of the smart watch described above with respect to FIG. 2.

As described above, when the user wears the smart watch so that the display unit 3010 is located on the same side as the back of the hand, the user frequently takes a gesture to bring the back of the hand wearing the smart watch into the user's field of view 3050. I can. The smart watch of the present specification may perform a certain command according to the rotation directions 3030-1 and 3030-2 and the rotation angle based on the position state of the smart watch. Therefore, in the present specification, the position state of the smart watch is referred to as a reference position, and the reference position will be described in detail later.

As an embodiment, the reference position of the smart watch may indicate a state in which the front surface 3010 of the display unit provided in the smart watch faces a preset direction. In more detail, the reference position of the smart watch may indicate a state in which the front surface 3010 of the display unit faces upward. In more detail, as shown in the drawing, it may represent a state in which the user has positioned the back of his hand upward to view the smart watch. However, the upper side here represents the actual upper side. Therefore, a certain range of errors can be tolerated. For example, a state in which the front surface 3010 of the display unit faces upward may include a case where the angle formed by the normal lines 300-1 and 3040-2 of the display unit front 3010 with the ground surface is 70 degrees to 110 degrees. have. The smart watch may detect the reference position of the present embodiment by obtaining the tilt of the smart watch using the tilt sensor unit described above with respect to FIG. 1.

In addition, the reference position of the smart watch may be a state in which the front surface 3010 of the display unit faces downward. For example, when the user looks at the smart watch while lying down, the reference position of the smart watch may be a state in which the front surface 3010 of the display unit faces the lower side instead of the upper side. At this time, the smart watch may detect whether the user is lying down using the tilt sensor unit. When the smart watch detects that the user is lying down, a position in which the front surface 3010 of the display unit faces downward may be determined as a reference position. However, the lower side here represents a substantial lower side, and a certain range of errors may be allowed.

Meanwhile, in this embodiment, the front surface 3010 of the display unit may represent a display area located on the back of the user's hand. For example, in the case of a smart watch composed of one flexible display panel, a display area located on the back of a user's hand among the areas of the flexible display may be referred to as the front surface 3010 of the display unit.

As another embodiment, when a user image is detected through a camera unit, the reference position of the smart watch may indicate the position of the smart watch at the detected time point. That is, when a user image is detected through the camera unit, the position of the smart watch at the detected time point may be the reference position. Accordingly, when the smart watch senses the rotation of the smart watch after the user image is detected, the smart watch may execute a certain command according to the rotation directions 3030-1 and 3030-2 and the rotation angle of the smart watch.

Accordingly, the reference position in the present embodiment may not necessarily face the front side of the display unit, unlike the above-described embodiment. For example, when a user image is detected by looking at the display unit while the user is lying down, the smart watch determines the current position as the reference position and issues a certain command corresponding to the rotation, even if the front of the display unit is not facing upward. On the other hand, in the present specification, it is as described above with reference to FIG. 1 that the user image may include the user's face and the user's gaze 3050.

The above-described embodiments may be implemented as a method for detecting the reference position of the smart watch, respectively, and may be implemented by a combination of the respective embodiments. Furthermore, it is revealed that the detection method can be freely changed within the range acceptable to those skilled in the art according to device design, design, and user settings.

As such, when it is detected that the current position of the smart watch is the reference position, the smart watch can then acquire the rotation direction and rotation angle of the smart watch. In more detail, when the rotation of the smart watch is sensed based on the rotation axis 3020 of the smart watch, the rotation directions 3030-1 and 3030-2 and the rotation angle may be obtained. Here, the rotation axis of the smart watch may include a center line penetrating the wrist or an outer boundary line 3020 of the back of the hand as an embodiment. Hereinafter, for convenience of explanation, a smart watch that rotates using the outer boundary line 3020 of the back of the hand as a rotation axis will be described. In addition, the rotation of the smart watch may indicate rotation in the reference position state of the smart watch, even if not described in duplicate below.

Next, the smart watch may execute a certain command according to the obtained rotation directions 3030-1 and 3030-2 and the rotation angle, and a more detailed description thereof will be described later with reference to FIG. 4.

4 is a diagram illustrating a smart watch rotating about a rotation axis according to an exemplary embodiment. In more detail, it is a view showing a scene as viewed from the front of the rotation of the wrist wearing the smart watch 4030.

The smart watch 4030 may rotate in a first direction or a second direction with respect to the rotation shaft 4020 in the reference position state 4010. In more detail, the smart watch 4030 may rotate in the first direction or the second direction according to the user's wrist rotation gesture in the above-described reference position state 4010.

When the rotation in the first direction is sensed in the reference position state 4010 of the smart watch 4030, the smart watch 4030 may acquire a first rotation angle, which is a rotation angle in the first direction. In this case, as an embodiment, the smart watch 4030 may acquire a rotation angle by sensing a degree of inclination using a tilt sensor unit. Alternatively, as another embodiment, the smart watch 4030 may obtain a rotational speed using a tilt sensor unit to obtain a rotation angle through a constant calculation.

When the obtained first rotation angle exceeds the first threshold angle θ1, the smart watch 4030 may execute a first command corresponding to the first direction. Likewise, when rotation in the second direction is sensed in the reference position state 4010 of the smart watch 4030, the smart watch 4030 may acquire a second rotation angle that is a rotation angle in the second direction. Here, the second rotation angle of the smart watch 4030 may also be obtained using a tilt sensor unit, as described above. When the obtained second rotation angle exceeds the second threshold angle θ2, the smart watch 4030 may execute a second command corresponding to the second direction. In this case, the first threshold angle θ1 may be greater than the second threshold angle θ2.

The first threshold angle θ1 should be greater than the second threshold angle θ2, as described above with respect to FIG. 2, according to the user's body structure, the reference position state 4010 of the smart watch 4030 This is because the radius of rotation in the first direction is larger than the radius of rotation in the second direction. As described above, it is possible to prevent malfunction of the smart watch 4030 by specifying different threshold angles θ1 and θ2 according to the rotation direction.

Meanwhile, the first threshold angle θ1 and the second threshold angle θ2 may be determined according to the design of the smart watch 4030, the design, the type of application being executed, the user's setting, and the user's physical structure. have. Furthermore, the first threshold angle θ1 and the second threshold angle θ2 may be determined as an absolute angle value as well as a relative angle value. A more detailed description of this will be described later with reference to FIG. 5.

5 is a diagram illustrating a smart watch that rotates about a rotation axis according to an exemplary embodiment. More specifically, it is a view showing a scene from above looking down on the rotation of a wrist wearing a smart watch.

The smart watch may be positioned so that the front surface 5010 of the display unit faces upward, as shown in the drawing. Alternatively, the smart watch may be positioned so that the front surface 5010 of the display unit is exposed to the user's gaze. It is as described above with reference to FIG. 4 that the position state of the smart watch at this time may be referred to as a reference position.

Next, the smart watch can rotate according to the user's wrist movement. In more detail, the smart watch may rotate outward 5020-1 in the reference position state, as shown in FIG. 5-(a). Alternatively, the smart watch may rotate in the upper direction 5020-1 of the display unit in the reference position state, as shown in FIG. 5-(a). Conversely, the smart watch may rotate inward 5020-2 in the reference position, as shown in FIG. 5-(b). Alternatively, the smart watch may rotate in the lower direction 5020-2 of the display unit in the reference position state, as shown in FIG. 5-(b).

At this time, when the rotation degree of the smart watch exceeds a preset threshold value, the smart watch may execute a command according to the rotation direction. In this case, the first direction 5020-1 corresponds to the first threshold angle, and the second direction 5020-2 corresponds to the second threshold angle as described above.

The first threshold angle and the second threshold angle may be fixed to absolute angle values according to the design of the smart watch. For example, the first threshold angle may be fixed at 30° and the second threshold angle may be fixed at 10°. That is, when sensing that the smart watch rotates more than 30° in the first direction 5020-1 from the reference position, the smart watch may execute a first command corresponding to the first direction 5020-1. . Alternatively, when sensing that the smart watch rotates more than 10° in the second direction 5020-2 from the reference position, the smart watch may execute a second command corresponding to the second direction 5020-2. .

Alternatively, the first threshold angle and the second threshold angle may be determined relatively. In more detail, when the threshold angle value in one direction is determined, the threshold angle value in the other direction may be determined relative to the predetermined angle value. For example, the smart watch may specify a difference between the first threshold angle and the second threshold angle as 20°. Accordingly, when the first threshold angle is determined to be 30°, the smart watch may determine the second threshold angle as 10° through calculation. Conversely, when the second threshold angle is determined to be 10°, the smart watch may determine the first threshold angle to be 30° through calculation.

As another embodiment, the smart watch may specify a ratio of the first threshold angle and the second threshold angle to 2:1. Accordingly, when the first threshold angle is determined to be 30°, the smart watch may determine the second threshold angle as 15° through calculation. Alternatively, when the second threshold angle is determined to be 15°, the smart watch may determine the second threshold angle to be 30° through calculation.

That is, when a threshold angle value in one direction is determined, the smart watch may designate a threshold angle value in another direction corresponding to the determined threshold angle value.

In addition, the threshold angle value may be determined according to the smart watch setting, design, running application and/or user setting, and is not limited to the above-described embodiment.

6 is a diagram illustrating a smart watch that executes a command according to the rotation of the smart watch, according to an exemplary embodiment.

As an embodiment, the smart watch may determine the type of command to be executed according to the type of application currently being executed. In more detail, the smart watch may determine the type of command corresponding to the rotation of the smart watch according to an application currently being executed. Alternatively, the smart watch may determine the type of command to be executed according to the currently displayed application execution screen. In more detail, the smart watch may determine the type of command corresponding to the rotation of the smart watch according to an application execution screen currently being displayed.

For example, when the music play application 6010 is running, the smart watch may perform volume control commands 600-1 and 6030-2 according to the rotation of the smart watch. In more detail, while the music play application 6010 is running, when the smart watch is rotated outward with respect to the rotation axis (6020-1), the smart watch may execute a volume-up command 600-1. Alternatively, while the music play application 6010 is running, when the smart watch is rotated inward 6020-2 with respect to the rotation axis, the smart watch may execute a volume-down command 6030-2. As such, it is possible to provide a user with an easier and more convenient control method of the smart watch by determining the command type according to the type of the currently running application 6010.

In addition, the smart watch may execute various commands such as an audio/video playback control command, an image enlargement/reduction control command, an execution control command, and a scroll control command according to the running application 6010. However, the type of command is not limited to the above-described embodiment, and may include various control commands for the smart watch.

Also, commands executed according to the rotation directions 6020-1 and 6020-2 of the smart watch may correspond to each other. In other words, the first command and the second command may correspond to each other. For example, when the first command is a volume-up command 6030-1, the second command may be a volume-down command 6030-2. Alternatively, when the first command is a scroll-up command, the second command may be a scroll-down command. As described above, the smart watch of the present specification can provide an easier and more intuitive control method for the smart watch by mutually corresponding two commands executed according to the rotation directions 6020-1 and 6020-2.

Furthermore, as an additional embodiment, the smart watch may provide a directional indicator indicating a direction of rotation for command execution. A more detailed description of this will be described later with reference to FIG. 7.

Meanwhile, although not shown in the drawings, the smart watch can also control an external device paired with the smart watch according to the rotation of the smart watch. For example, when a smart watch is paired with a smart phone through a communication unit, the smart watch can control the smart phone according to the rotation of the smart watch. In more detail, when the music player application 6010 is running on the smart phone, the user may perform volume control commands 600-1 and 6030-2 for the smart phone through rotation of the smart watch.

The purpose of this is to increase accessibility to external devices by allowing a user to control an external device through a smart watch with high accessibility and portability when a user uses a pair of devices. Therefore, according to the present embodiment, the user can indirectly control the external device by using the rotation of the paired smart watch without direct control of the external device.

7 is a diagram illustrating a smart watch in which an event has occurred according to an exemplary embodiment.

In the smart watch of the present specification, certain events may occur according to embodiments. Here, the event may represent a state change occurring in the smart watch. For example, the event may include receiving a call, receiving a text message, receiving a new message from a social networking service (SNS), a schedule notification, an alarm, an update notification, and a weather notification. In this case, the smart watch may provide a notification 7010 for an event that has occurred. The notification 7010 may represent an operation informing a user that the above-described event has occurred. In this specification, the notification 7010 may include auditory, visual, and tactile notifications.

When the notification 7010 for the event is provided and rotation of the smart watch is sensed within a preset time Tr, the smart watch may execute a command corresponding to the event or notification.

For example, when a call reception event occurs, the smart watch may provide a notification 7010 regarding the occurrence of a call reception event. When the rotation of the smart watch is sensed within a preset time (Tr) after the notification 7010 is provided, the smart watch executes a certain command corresponding to the call reception event or the call reception notification 7010 according to the rotation. can do. In more detail, when the call reception notification 7010 occurs and the rotation of the smart watch in the first direction 700-1 within a preset time Tr is sensed, the smart watch rejects the received call. Can (reject) (7040). Alternatively, when a call reception notification 7010 occurs and a rotation of the smart watch in the second direction 7030-2 is sensed within a preset time Tr, the smart watch can receive the received call ( accept)(7050).

For another example, when a text reception event occurs, the smart watch may provide notification of the event. After providing such notification, if the rotation of the smart watch is sensed within a preset time Tr, the smart watch may perform a command to check or ignore the text message received according to the rotation.

However, when the rotation of the smart watch is sensed after the notification 7010 has occurred and a preset time Tr has elapsed, the event or a command corresponding to the notification 7010 may not be executed. In this case, depending on the embodiment, returning to the embodiment described above with respect to FIG. 6, when the rotation of the smart watch is sensed, a command designated according to the type of the running application may be executed.

In the exemplary embodiment related to the drawing, the command according to rotation is a command corresponding to an event occurring in the smart watch, and may be a command that executes or ignores the mainly occurring event. However, the type of the command according to the rotation is not limited to the above-described embodiment, and there may be embodiments of various commands corresponding to the event or notification 7010.

In addition, the smart watch may execute a command corresponding to the event or notification 7010 in preference to a command corresponding to the currently executing application. For example, as described above with respect to FIG. 6, when the rotation of the smart watch is sensed during execution of the music play application, the smart watch may perform a volume control command according to the rotation. However, when a call is received while the music play application is running and a notification 7010 for the received call is provided, the smart watch may perform an event control command prior to the volume control command according to the rotation of the smart watch. .

Meanwhile, when the smart watch provides the notification 7010 for an event, it may also provide a direction indicator 7020 for command execution. In other words, when the notification 7010 is provided, the smart watch may also provide a directional indicator 7020 for guiding a rotation direction corresponding to each command. For example, when the smart watch provides a notification 7010 for a call reception event, it may also provide a downward indicator 7020 for performing a command to receive a received call. Alternatively, the smart watch may provide an upward direction indicator 7020 for performing a command to reject a received call.

The directional indicator 7020 may include a visual, audible, and tactile directional indicator according to embodiments, and is not limited to the above-described embodiments. Further, the directional indicator 7020 is not limited to a case in which the notification 7010 is provided, and may be provided in various cases where it is necessary to guide a rotation direction for performing a command.

8 is a diagram illustrating a smart watch that executes a command in response to a rotation speed according to an exemplary embodiment.

According to an embodiment, the smart watch may obtain the rotational speed V of the smart watch using a measurement unit. In more detail, the smart watch may obtain the rotational speed V of the smart watch using the measurement unit described above with respect to FIG. 1. For example, the smart watch may obtain a rotational speed (V) by measuring a change in inclination of the smart watch during a preset time. Alternatively, the smart watch may measure the force applied when the smart watch rotates, and obtain the rotation speed through a constant calculation from the measured force. Alternatively, the smart watch may measure the time until the smart watch rotates beyond the threshold angle, and obtain the rotational speed (V) through a constant calculation from the measured time.

The smart watch may execute a command according to the rotation of the smart watch when the obtained rotation speed V of the smart watch exceeds the threshold speed Vt. However, the smart watch may not execute a command according to the rotation of the smart watch when the rotation speed V of the smart watch is less than or equal to the threshold speed Vt. For example, while providing the call reception notification 8010, if the smart watch rotates in the first direction 8020 beyond the threshold speed Vt, the smart watch may reject the received call ( 8030). Conversely, when the smart watch rotates in the first direction 8020 below the threshold speed (Vt) while the call reception notification 8010 is provided, the smart watch may not perform an additional operation (8040). .

In the present specification, the rotational speed V may represent the degree of rotation of the smart watch for a preset time. In this case, if the measured rotation speed V is less than or equal to the threshold speed Vt, it may indicate that the smart watch is rotated below a preset angle for a preset time. This slow rotation can be difficult to see as a rotation for command execution. Therefore, in order to prevent the operation of the smart watch that deviates from the user's intention, a threshold speed (Vt) is specified, and the smart watch is set to execute a command only when the smart watch rotates above the threshold speed (Vt). Can be designed.

However, it may be difficult to see rotation of too high a speed as the rotation intended by the user to execute the command. This is because the rotation speed (V) can be measured to exceed the threshold speed (Vt) even when the user is performing a dynamic exercise, such as when running. Accordingly, in this case, by specifying a separate threshold angle Vt' in addition to the above-described threshold angle Vt, the rotation of the smart watch containing the user's intention can be more accurately detected. For example, by performing a command according to the rotation of the smart watch only when the first threshold speed is exceeded and the second threshold speed is less than the second threshold speed, a malfunction of the smart watch can be prevented. That is, depending on the embodiment, in order to prevent malfunction of the smart watch, a plurality of threshold speeds Vt may be designated.

In addition, the threshold speed Vt may be variously set according to the design, design, application field, type of application, and user of the smart watch, and is not limited to the above-described embodiment.

9 is a flowchart illustrating a method of controlling a smart watch according to an exemplary embodiment. In this flowchart, a detailed description of a portion similar to or overlapping with the description described above in FIGS. 1 to 8 will be omitted.

First, the smart watch may face the front of the display unit in a preset direction (S9010). In more detail, the smart watch may detect whether the front of the display unit is facing a preset direction. Here, the preset direction may indicate the upper side. Alternatively, the preset direction may indicate a direction indicated by the front of the display unit when a user image is detected through the camera unit. The smart watch can sense whether the front of the display unit faces a preset direction through the tilt sensor unit and the camera unit, and a more detailed description thereof is as described above with reference to FIGS. 3 and 4. In addition, the smart watch may additionally detect whether the mode is a worn mode or a non-wear mode through the input sensor unit, as described above with respect to FIG. 2.

Next, the smart watch may sense whether the smart watch rotates (S9020). In more detail, the smart watch may sense whether the smart watch rotates about the rotation axis.

If the rotation of the smart watch is sensed, the smart watch may additionally sense the rotation direction (S9030). In the present specification, the smart watch may rotate in an outward or inward direction, and an outward direction may be referred to as a first direction and an inward direction may be referred to as a second direction.

Meanwhile, when the rotation of the smart watch is not sensed, the smart watch may not perform an additional operation (S9010). Alternatively, when the rotation of the smart watch is not sensed, it may return to the previous step (S9010).

If it is sensed that the smart watch rotates in the first direction, a first rotation angle, which is a rotation angle in the first direction, may be obtained (S9040). Conversely, when sensing that the smart watch rotates in the second direction, a second rotation angle, which is a rotation angle in the second direction, may be obtained (S9070). The first rotation angle and the second rotation angle may be obtained using the tilt sensor unit, and a more detailed description thereof is as described above with respect to FIG. 1. Further, as an additional embodiment, the smart watch may measure the rotational speed in each rotational direction using a measurement unit, and a detailed description thereof is as described above with respect to FIG. 8.

Next, the smart watch may determine whether the first rotation angle or the second rotation angle obtained in the previous step exceeds the first threshold angle or the second threshold angle, respectively (S9050 and S9080). In more detail, the smart watch may determine whether the first rotation angle exceeds the first threshold angle (S9050). Alternatively, the smart watch may determine whether the second rotation angle exceeds the second threshold angle (S9080).

If the first rotation angle exceeds the first threshold angle, the smart watch may execute a first command corresponding to the first direction (S9060). Alternatively, when the second rotation angle exceeds the second threshold angle, the smart watch may execute a second command corresponding to the second direction (S9090). In this case, the first threshold angle may be greater than the second threshold angle. This is because, when the display unit faces a predetermined direction, the radius of rotation in the first direction is larger than the radius of rotation in the second direction, and a detailed description thereof is as described above with respect to FIG. 2. Also, the first command corresponding to the first direction and the second command corresponding to the second direction may correspond to each other. Also, the first command and the second command may be determined according to an application currently being executed or an execution screen of an application currently being displayed. A detailed description of this is as described above with reference to FIG. 6. Furthermore, when an event occurs in the smart watch and a notification for the event is provided, a command corresponding to the notification may be executed according to the rotation of the smart watch. In more detail, if the rotation of the smart watch is sensed within a preset time after the notification is provided, a command corresponding to the provided notification may be executed according to the sensed rotation. A more detailed description of this is as described above with reference to FIG. 7.

Meanwhile, when the first rotation angle does not exceed the first threshold angle, or when the second rotation angle does not exceed the second threshold angle, the smart watch may not perform an additional operation. Alternatively, when the first rotation angle does not exceed the first threshold angle, or the second rotation angle does not exceed the second threshold angle, the previous steps S9040 and S9070 may be returned.

For convenience of explanation, each drawing has been described separately, but it is also possible to design a new embodiment by merging the embodiments described in each drawing. In addition, it is also within the scope of the rights to design a computer-readable recording medium in which a program for executing the previously described embodiments is recorded according to the needs of those skilled in the art.

In addition, the smart watch and its control method are not limitedly applicable to the configuration and method of the described embodiments as described above, but the above-described embodiments are all or part of each embodiment selectively so that various modifications can be made. It may be configured in combination.

In addition, although preferred embodiments have been illustrated and described above, the present specification is not limited to the specific embodiments described above, and without departing from the subject matter claimed in the claims, those having ordinary knowledge in the technical field to which the specification belongs. Various modifications are possible by the person, and these modifications should not be individually understood from the technical idea or perspective of the present specification.

In addition, the smart watch and control method of the present specification can be implemented as code that can be read by a processor on a recording medium that can be read by a processor provided in a network device. The processor-readable recording medium includes all types of recording devices that store data that can be read by the processor. Examples of the recording medium readable by the processor include ROM, RAM, magnetic tape, floppy disk, optical data storage device, and the like, and also include those implemented in the form of a carrier wave such as transmission through the Internet. Further, the processor-readable recording medium is distributed over a computer system connected through a network, so that the processor-readable code can be stored and executed in a distributed manner.

In addition, angles, speeds, and directions in the present specification not only mean accurate values, but can be viewed as including a range of actual angles, speeds and directions. That is, the angle, speed, and direction of the present specification may represent a substantial angle, speed, and direction, and an error of a certain range may exist.

In addition, in the present specification, both the product invention and the method invention have been described, and the description of both inventions may be supplementally applied if necessary.

4010: reference position
4020: rotating shaft
4030: smart watch

Claims (22)

In the smart watch,
A tilt sensor unit sensing a tilt of the smart watch;
A display unit that displays an image; And
A processor that controls the tilt sensor unit and the display unit; Including,
The processor,
As a case where the front of the display unit faces a preset direction,
When sensing that the smart watch rotates in a first direction based on an axis of rotation of the smart watch, a first rotation angle in the first direction using the tilt sensor unit And, when the first rotation angle exceeds the first threshold angle, a first command corresponding to the first direction is performed,
When sensing that the smart watch rotates in a second direction based on the rotation axis, a second rotation angle in the second direction is obtained using the tilt sensor unit, and the second rotation angle is a second thread. When the threshold angle is exceeded, a second command corresponding to the second direction is executed,
The first direction is an opposite direction to the second direction,
The first threshold angle is greater than the second threshold angle, smart watch. The method of claim 1,
The first direction is an outward direction, and the second direction is an inward direction. The method of claim 1,
The processor,
As the mode of the smart watch, a wearing mode or a non-wearing mode is detected,
A smart watch that executes the first command or the second command according to the rotation of the smart watch based on the detected wearing mode or the non-wearing mode. The method of claim 3,
The processor,
When the mode of the smart watch is the wearing mode, the first command or the second command is executed according to the rotation of the smart watch,
When the mode of the smart watch is the non-wearing mode, the first command or the second command is not executed according to the rotation of the smart watch. The method of claim 3,
The processor,
When the mode of the smart watch is the wearing mode,
When sensing that the smart watch rotates in the first direction with respect to the rotation axis, the first rotation angle is obtained, and the obtained first rotation angle exceeds the first threshold angle, Execute the first command,
When sensing that the smart watch rotates in the second direction with respect to the rotation axis, the second rotation angle is obtained, and the acquired second rotation angle exceeds the second threshold angle, Execute the second command,
The first threshold angle is greater than the second threshold angle, smart watch. The method of claim 3,
An input sensor unit for sensing an input to the smart watch; Including more,
The processor,
The smart watch to determine the mode based on at least one of an input to a rear surface of the smart watch and an input to a buckle provided in the smart watch. The method of claim 1,
When the front side of the display unit faces a preset direction, the smart watch is when the front side of the display unit faces upward. The method of claim 1,
The processor,
A smart watch for determining the first command and the second command according to a type of an application currently being executed or an execution screen of an application currently being displayed. The method of claim 1,
The first command and the second command are commands corresponding to each other. The method of claim 1,
The first threshold angle is an angle relative to the second threshold angle, or
The second threshold angle is an angle relative to the first threshold angle, smart watch. The method of claim 1,
The first direction is an upper direction of the display unit, the second direction is a lower direction of the display unit, smart watch. The method of claim 1,
The processor,
When an event occurs in the smart watch, a notification on the event is provided,
When the notification is provided and the rotation of the smart watch is sensed within a preset period, the smart watch performs the first command or the second command corresponding to the notification according to the rotation. Watch. The method of claim 12,
The first command and the second command corresponding to the notification respectively correspond to one of an ignore command or an execution command. The method of claim 1,
A measuring unit measuring the rotational speed of the smart watch; Including more,
The processor,
When sensing the rotation of the smart watch, obtains a rotation direction, a rotation angle, and a rotation speed of the smart watch,
When the obtained rotation speed exceeds a predetermined speed, the first command or the second command is executed according to the rotation direction and rotation angle of the smart watch,
When the obtained rotation speed is less than or equal to the predetermined speed, the first command or the second command is not executed according to the rotation direction and rotation angle of the smart watch. The method of claim 1,
A communication unit that transmits and receives data; It further includes,
The processor,
A smart watch for performing pairing between the smart watch and an external device using the communication unit. The method of claim 15,
The processor,
A smart watch for controlling the external device paired with the smart watch according to the rotation direction and rotation angle of the smart watch. The method of claim 1,
A camera unit capturing the front of the smart watch; It further includes,
The processor,
A smart watch that detects a user's image using the camera unit. The method of claim 17,
The processor,
When the image of the user is detected, the first command or the second command is executed according to the rotation direction and rotation angle of the smart watch,
When the user's image is not detected, the first command or the second command is not executed according to a rotation direction and a rotation angle of the smart watch. The method of claim 17,
The preset direction is a front direction of the display unit when the image of the user is detected. The method of claim 1,
The processor,
A smart watch that provides a directional indicator indicating the first direction or the second direction. delete delete

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